JPH05313563A - Intelligent laser pointer and overhead projector - Google Patents

Abstract

PURPOSE:To efficiently execute a presentation by remotely controlling an OHP device, and other environment controller of illumination, etc., at the time of executing the presentation by utilizing the OHP device. CONSTITUTION:An ILP(intelligent laser pointer) 5 is provided with a remote control means in addition to a laser pointer for indicating an image on a screen by a laser light. By the remote control means, a transmitting signal is sent to a photodetecting circuit 41A. The photodetecting circuit 41A outputs received data, by which an environment controller of a lighting device I8, etc., is operated. A publisher, etc., can operate various devices required for a presentation by operating only the ILP 5, and the movement for operating these devices becomes unnecessary.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an intelligent laser pointer and an overhead projector for pointing a pointing portion of an image projected by a projector such as an OHP device with a laser beam.

[0002]

2. Description of the Related Art Generally, at a presentation or lecture using an OHP device, a presenter or the like writes image information on a transparent sheet-shaped OHP film to create a manuscript film (hereinafter referred to as "sheet"). The sheet is set on the platen glass of the OHP device, and light is irradiated from below to enlarge and project the original image on the front screen.
The presenter stands next to the screen and gives an explanation to the viewer while pointing the magnified image on the screen with a pointing stick or the like. When the description of one sheet is completed, this sheet is removed from the platen glass, and a new sheet necessary for the next description is placed on the platen glass. In this way, by repeating the removal of the already described sheet and the placement of a new sheet, the presenter exchanges the sheets prepared in advance in the order of presentation on the platen glass one after another, and replaces each sheet. Will be sequentially explained on the screen.

In such a presentation,
As a pointer that points to an image on the screen, a pointer that uses light in addition to a pointer is known. This one is
A laser oscillator is provided, and the laser light emitted from this laser oscillator is used instead of the indicator rod.

[0004]

However, according to the above-described conventional example, the presenter approaches the OHP device and presents while exchanging the sheets on the platen glass one by one. There was such a drawback. (1) The OHP device and the screen are usually installed at a distance from each other, and therefore the presenter or the like needs to move from the screen to the OHP device when replacing the sheet, which is inefficient. For this reason, the presenter or the like may be attached to the screen, another person may be arranged for the sheet exchange, and the sheet may be exchanged at the signal of the presenter or the like. (2) When answering a question after the presentation, it takes time to find a necessary sheet out of the randomly placed already presented sheets, and the limited presentation time cannot be effectively utilized. (3) At the start and end of the presentation, the lights are turned off and on respectively, and the light source of the OHP device is turned on / off.
In order to perform the work of F in a timely manner, a large number of staff members are required, and the limited time cannot be effectively utilized. (4) A large number of staff members are required to make effective presentations by changing the volume of the microphone and BGM at the beginning and end of the presentation. (5) For long presentations, a large number of staff members are needed to control the air conditioning such as temperature, ventilation and humidity to give a comfortable presentation. (6) A large number of staff members are required to perform the work of closing and closing the blinds at the start and end of the presentation in a timely manner, and the limited presentation time cannot be effectively utilized.

In order to solve the above-mentioned drawbacks, an automatic document feeder for feeding a document sheet onto a platen glass can be considered.

However, if the operation section for activating the automatic document feeder is simply arranged on this device, the presenter moves to the immediate vicinity or operates this device in order to point the image on the screen with the pointing stick. The inconvenience of moving to the device in order to do so arises. As a result, it may be difficult to give an orderly presentation.

Further, even if environmental control devices for lighting, sound volume, air conditioning, room management, etc. are arranged near the presenter, it is inconvenient to move to the device to operate these devices. Furthermore, even if there are a plurality of remote control devices that can be remotely controlled, the presenter's operation may become complicated, and it may be difficult to give an orderly presentation.

Therefore, the present invention is to provide an intelligent laser pointer and an overhead projector equipped with the intelligent laser pointer, in which the laser pointer is provided with remote control means for controlling the presentation environment to enable efficient presentation. It is intended.

[0009]

The present invention has been made in view of the above circumstances, and an intelligent laser pointer (5) is a laser pointer (pointing an image projected by a projector (1) by a laser beam ( In 5), remote control means (5a) for generating a signal for controlling the presentation environment is integrally incorporated.

In this case, the projector (1) projects the original film (D) on the OHP device (1) and the original film (D) at a predetermined position on the platen glass (7) of the OHP device (1). Automatic document feeder (2)
And the OHP device (1) and the automatic document feeder (2)
It is preferable that the remote control means (5a) is configured by remotely controlling the control means (42) while it is configured by an OHP system (3) including a control means (42) for controlling the.

Further, the laser pointer (5) generates a signal for controlling the light source, and the lighting remote control means (I ₈ ) is provided.
(See FIG. 9) A for generating a signal for controlling the volume
V remote control means (I ₉ ), air conditioning remote control means (I ₁₀ ) for generating a signal for controlling at least one of temperature, ventilation and humidity, room management for generating a signal for controlling lighting A remote control means (I ₁₁ ) may be provided.

The laser pointer (5) may have a common drive source with the remote control means, and may have a pointing direction in the same direction as the directivity of the remote control means.

Further, an overhead projector (3)
Is an OHP device for placing an original film (D) formed by writing image information on a transparent film on a platen glass (7) and irradiating the original film (D) with light to project image information. (1) and the intelligent laser pointer (5) described above.

[0014]

With the above configuration, for example, the remote control means (5a) for controlling the presentation environment such as the light source and the volume.
By integrally incorporating in the laser pointer (5), the presenter, etc., while staying at a position suitable for pointing the image on the screen with the laser pointer (5),
The light source, volume, etc. can be controlled. Moreover, these controls can be performed at the optimum timing for the presenter at will.

[0015]

Embodiments of the present invention will be described below with reference to the drawings.

The intelligent laser pointer 5 is formed by integrally incorporating remote control means into the laser pointer. The remote control means controls the automatic document feeder, lighting, volume, air conditioning, room management, etc. First, the case of controlling the automatic document feeder mounted on the OHP device will be described.

As shown in FIG. 1, the overhead projector 3 includes an OHP device 1 and a document film feeding device, and the document film feeding device 2 is an automatic document feeding device (hereinafter referred to as “sheet feeder”) 2. And an intelligent laser pointer 5.
The intelligent laser pointer 5 includes a laser pointer (described later), an OHP device 1 and a sheet feeder 2.
The remote control light-emitting device (remote control transmission unit) 5a as a remote control means for operating from a remote location. Note that FIG. 1 illustrates a vertical cross-sectional view of the OHP device 1 and the sheet feeder 2 and an enlarged perspective view of the remote control light emitting device 5a. FIG. 2 is a development view of the drive system when the sheet feeder 2 is viewed from above. Further, in the following description, with respect to the front, rear, left, and right positions, with reference to FIG. 2, which is a top view of the sheet feeder 2, the lower side is referred to as the front, the upper side is referred to as the rear, the left side is referred to as the left, and the right side is referred to as the right.

The OHP device 1 has a device body 6 formed in a box shape, a transparent platen glass 7 is provided on the upper surface thereof, and a light source 9 is provided inside thereof.
An irradiation unit 100 irradiates the screen with light from the sheet document.

The sheet feeder 2 is provided with front and rear side plates 10a and 10b, which are respectively arranged at the front and rear and face each other, and a large number of rollers rotatably supported by these side plates 10a and 10b. A lower right roller 11 and an upper right roller 12 forming a take-up roller are rotatably arranged on the right side portion of the sheet feeder 2, and a left roller 13 forming a rewinding roller rotates on the left side portion. It is arranged freely. As shown in FIG. 2, the lower right roller 11 is a lower right roller front pulley which is rotatably loosely fitted to both front and rear ends of a lower right roller shaft 11c whose front and rear ends are fixedly supported by front and rear side plates 10a and 10b. 11a, lower right roller rear pulley 11b, and these pulleys 11a, 11b
Has a lower right roller cylinder 11d fitted to both front and rear ends. Therefore, the lower right roller 11 as a whole includes the lower right roller shaft 1
It is rotatable with respect to 1c. Lower right roller rear pulley 11
A gear portion 11e is formed outside b, and the right pulley gear 15 meshing with the gear portion 11e is an output shaft 16a of a film winding motor 16 including a stepping motor.
It is fixed to. Therefore, in the lower right roller 11,
Through the right pulley gear 15, a film winding motor 16
Is directly transmitted.

A pulley 17 integral with the right pulley gear 15 is fixed to the output shaft 16a of the film winding motor 16, and a belt 20 is stretched between the pulley 17 and a pulley 19 forming a pair. As a result, the rotational force of the film winding motor 16 is applied to the upper right roller 1 which will be described later.
2 has been transmitted. The pulley 19 is fixed to a transmission shaft 21 extending outside the rear side plate 10b, and a one-way gear 22 is attached to the transmission shaft 21 via a one-way clutch (not shown). An upper right gear 23 meshing with the one-way gear 22 is connected to a shaft 26 via a torque limiter 25, and a brake plate 27 is fixed to an inner portion of the side plate 10b of the shaft 26. A brake spring 29, which is a compression spring, is interposed between the brake plate 27 and the side plate 10b to urge the brake plate 27 inward. The upper right roller rear pulley 12b, which the biased brake plate 27 slides on, is fixed to the rear end side of the upper right roller shaft 12c, and on the front end side of the upper right roller shaft 12c,
The right upper roller front pulley 12a is fixed. Further, these pulleys 12a and 12b are cylindrical upper right roller cylinders 1
It is fitted to both front and rear ends of 2d. That is, the power of the film winding motor 16 is transmitted to the upper right roller 12 which mainly includes the upper right roller cylinder 12d, but the one-way gear 22, the torque limiter 25, the brake plate are provided between them. As for the rotation of the upper right roller 12, the driving force is transmitted in one direction, the transmission of power more than a predetermined amount is prevented, and the braking force always in the opposite direction to the rotation direction is provided. Is designed to work. Regarding the peripheral speed of the upper right roller 12 and the peripheral speed of the lower right roller 11 described above, the reduction ratio is set so that (the peripheral speed of the upper right roller 12)> (the peripheral speed of the lower right roller 11). There is. These considerations for the upper right roller 12 are that the conveying film 36 and the pressing film 37, which will be described later, are moved (conveyed) in either the left or right direction, that the thicknesses of the films 36 and 37 are different,
Even if the peripheral speeds of the rollers 11 and 12 are constant, the film transport speed is delicately changed by changing the winding amount of the films 36 and 37 around the rollers 11 and 12, that is, the winding diameter of the film roll. It is based on things such as changing. As a result, the film 36,
The smooth transport of 37 is realized.

A lower sheet feeding roller 30 and an upper sheet feeding roller 31 (see FIG. 1) are provided between the upper right roller 12 and the lower right roller 11.
And are rotatably arranged so as to abut each other.
The lower sheet feeding roller 30 includes front and rear side plates 10a, 1
0b is provided with pulleys 30a and 30b rotatably loosely fitted to the front and rear ends of a shaft 30c. These pulleys 30a and 30b are cylindrical lower feed roller cylinders 3
It is fitted on both front and rear ends of 0d. The upper paper feed roller 31 is
The lower sheet feeding roller 30 has the same structure as that of the lower sheet feeding roller 30 and is rotatable, and is pressed against the lower sheet feeding roller 30 with an appropriate force.

The left roller 13 arranged on the left side portion of the sheet feeder 2 has a cylindrical left roller cylinder 13d in which a left roller front pulley 13a and a left roller rear pulley 13b are fitted at both front and rear ends, respectively. The left roller cylinder 13d is connected to the front and rear side plates 10 via the front and rear pulleys 13a and 13b.
It is rotatably supported by the left roller shaft 13c supported by a and 10b. A gear portion 13e is formed on the rear pulley 13b, and a left pulley gear 32 meshing with the gear portion 13e is fixed to an output shaft 33a of a film feed motor (for example, a stepping motor) 33. A left tension roller 35 is arranged on the lower right side of the left roller 13. The left tension roller 35 is rotatably supported by shafts 35c fixed to the front and rear ends of the left tension roller cylinder 35d, and front and rear pulleys 35a and 35b fixedly supported by the front and rear side plates 10a and 10b. The above six rollers 11, 12, 13, 30, 31,
35, the lower right roller 11, the upper right roller 12, and the left roller 13 are positively driven by the film winding motor 16 or the film feeding motor 33, respectively, while the lower paper feeding roller 30 is used. The upper paper feed roller 31 and the left tension roller 35 are so-called negative rotations to which a rotational force is applied by the transport film 36 described below.

These rollers, as shown in FIG.
The transport film 36 and the pressing film 37 are wound around. The transport film 36 and the pressing film 37 both have excellent transmittance because they transmit light from the power source 9 with the sheet as the original film sandwiched from above and below (front and back) on the platen glass 7 described above. Films such as PET films are used. These films 37 and 36 are wound around a left roller 13 on the left side of the sheet feeder 2 in a state of being vertically stacked, and are wound around a left tension roller 35, and passed through an upper surface of the platen glass 7 to a lower sheet feeding roller. 30 is guided to a nip portion between the upper sheet feeding roller 31 and the upper sheet feeding roller 31, and then separated into upper and lower parts, the transport film 36 is wound around the lower right roller 11, and the pressing film 37 is wound around the upper right roller 12. Has been. These films 36 and 37 are wound and unwound in any case.
Appropriate tension is applied by the left tension roller 35, the lower paper feed roller 30, the upper paper feed roller 31, and the like.

Further, a sheet feeding table 39 is arranged between the lower right roller 11 and the upper right roller 12 on the right side portion of the sheet feeder 2. The sheet feeding base 39 is swingably supported around the lower right roller shaft 11c described above, and its tip is located near the nip portion between the lower feeding roller 30 and the upper feeding roller 31. Are arranged as follows. On the lower surface side of the sheet feeding table 39, a tray swing cam 40 that contacts the sheet feeding table 39 is arranged. By rotating the tray swing cam 40, the sheet feeding table 39
The leading end of the sheet feeding table 39 is pushed up against the conveying film 36, and the sheet on the conveying film 36 is scooped up and collected on the sheet feeding table 39.

The sheet feeder 2 has sensors arranged at appropriate positions. A sheet R detection sensor A ₂ for detecting the length and width of a sheet placed on the sheet feeding table 39 is arranged on the right side portion of the sheet feeding table 39, and near the left side portion of the sheet feeding table 39. Is the sheet detection sensor A
₁ is placed. The sheet detection sensor A ₁ has a detection lever A ₁₀ that swings when a sheet is placed on the sheet feeding table 39, and a transmissive sensor detects the displacement of the detection lever A ₁₀ to detect the sheet. The presence or absence of is detected. Further, a path switching sensor A ₄ for switching the path of the sheet is also arranged in association with the detection lever A ₁₀ . Further, a sheet position detection sensor A ₃ is arranged between the lower right roller 11 and the lower paper feed roller 30. This sensor A _{3 is} also composed of a transmissive sensor, and has a light-shielding frame mark (described later) 3 attached to the transport film 36.
6a is, by blocking the optical path to the light receiving unit from the light projecting portion of the sensor A _3, and is configured to sense the position of the sheet.

FIG. 3 shows the platen glass 7 of the OHP device 1.
It is the figure which looked at from above. On the platen glass 7, the sheet D (two-dot chain line in the figure) sandwiched between the transport film 36 and the pressing film 37 is placed, and the sheet D
Is emitted from below by the above-mentioned light source 9 below the platen glass 7, and an image is projected on a screen (not shown) by the reflected light and the transmitted light. A large number of frame marks 36a are arranged for each frame (corresponding to one sheet) near one side edge of the transport film 36, and the frame position detection sensor A ₃ detects the frame marks 36a. As a result, the conveyance of the conveyance film 36 and the pressing film 37 is immediately stopped, and the sheet D is stopped and positioned in a predetermined image area on the platen glass 7 (approximately the same as the entire surface of the platen glass 7). The frame marks 36a, 36a adjacent to each other
The pitch P between them is a horizontal or vertical sheet D between them.
Should be set to such an extent that can be suitably arranged.

Further, on the upper surface of the right side portion of the sheet feeder 2, a remote control receiver 41 which constitutes a part of remote control means is provided (see FIG. 1). Then, the remote control light-emitting device 5a constituting the remote control means I and the remote control receiving unit 41 coupled with, the remote emission device 5a as a light emitting means, the button B ₁ feed one, one return button B _2, fine adjustment Feed button B ₃ , fine adjustment return button B ₄ , sheet discharge button B ₅ , preset button B ₆ , stop button B
₇ , each button of the laser pointer button B ₁₂ is arranged. The remote control light emitting device 5a emits infrared rays (light) corresponding to the command instructed by these buttons B,
The control means 42, which will be described later, is operated via the remote control receiver 41.

Next, referring to FIG. 4, the sheet feeder 2
The outline of the control will be described, and more specific control contents will be described with reference to the block diagram shown in FIG. Regarding the relationship between FIG. 4 and FIG. 5, components having the same function, such as the sheet detecting means A ₂ and the sheet detecting sensor A ₂ , are designated by the same reference numerals. From a different point of view, it can be said that FIGS. 4 and 5 show a relationship between a superordinate concept and a subordinate concept (or “means” and “specific member”).

The control means 42 shown in FIG. 4 is for controlling the entire sheet feeder 2. The following means are connected to the control means 42. These are remote control receiving means 4 for operating the sheet feeder 2 remotely.
1, two transport films 36 wound in a roll,
A sheet detecting means A ₁ for detecting that the sheet D sandwiched between the pressing films 37 is set on the sheet feeding table 39, and a sheet R detecting means A for detecting whether the sheet D is in the portrait orientation or the landscape orientation. ₂ , sheet position detecting means A ₃ for detecting that one sheet D has arrived on the platen glass 7, two sheet D sandwiched between a conveying film 36 and a pressing film 37 having different thicknesses, and a sheet feeder 2
Of the path switching means A ₄ for selecting whether the paper is to be stored inside or discharged to the outside, and the driving means 33 and 16 for conveying the conveying film 36 and the pressing film 37.

FIG. 5 shows the sheet feeder 2 shown in FIG.
The specific configuration of each of the means shown in FIG. 2 is shown, and the configuration is centered around a well-known one-chip microcomputer (hereinafter referred to as "MCOM") 42 having a built-in ROM, RAM, etc. as the control means. As inputs to the MCOM 42, a remote control receiving circuit 41 that receives a signal from a remote control light emitting device 5a that is capable of remote control, a sheet detection sensor A ₁ that detects a sheet D, and a sheet D portrait or landscape document. Inputs of a sheet R detection sensor A ₂ that detects whether the sheet is fed, a sheet position detection sensor A ₃ that detects the position of the sheet D that has been fed and conveyed, and a path switching sensor A ₄ that detects that the sheet path has been switched. The members are connected. Further, an output signal is sent from the MCOM 42 to the film feed motor 33 via the constant current circuit 33b driving the film feed motor 33, and via the constant current circuit 16b driving the film take-up motor 16 to the film take-up motor 1
6 is configured to be transmitted. These film feed motor 33 and film winding motor 16 are M
The COM 42 and the constant current circuits 33b and 16b are connected to each other. These connections are connected by four-phase signals, that is, signal lines A *, A, B *, and B during this period, and the remote controller The signal of the receiving circuit 41 is an ON / OFF signal according to a command from the MCOM 42, and is output as a constant current circuit 33.
It is transmitted to the film feed motor 33 and the film winding motor 16 via b and 16b. Phase signal (A * → A →
The film feed motor 33 and the film winding motor 1 are changed by periodically changing ON / OFF of B * → B).
6 rotates forward and the opposite phase signal (B → B * → A → A
*) To provide these motors 33, 16
Reverse rotation can be performed.

FIG. 6A shows the circuit configuration of the light receiving circuit 41A of the remote control receiver 41. The infrared signal from the remote control light emitting device 5a is received by one or several light receiving units 41a and converted into a serial electric signal. This is input to the processing circuit 41c via the buffer 41b. The processing circuit 41c converts the input serial data into parallel data and outputs the parallel data from the output port 41d. The clock circuit 41e is used for data acquisition timing and internal clock.

FIG. 6 (b) shows the internal structure of the light receiving unit 41a in FIG. 6 (a). Photodiode 41
by a _1, it converts the infrared signal from the remote control light-emitting device 5a into an electrical signal, amplified by an amplifier 41a _2. Next, the limiter 41a ₃ limits the amplitude of the signal, the bandpass filter 41a ₄ extracts only the signal of a specific frequency, and the demodulator 41a ₅ demodulates the signal. Integrator 41
The waveform is shaped by a ₆ , and finally the signal is passed through the comparator 41a _{7 so} that only a signal having a certain level or higher is output.

FIG. 7 shows a remote control light emitting device 5a for transmitting to the remote control receiver 41 described above. The remote control light emitting device 5a shown in FIG. 7 (b) is obtained by adding more preferable functions such as the illumination button B ₈ to the remote control light emitting device 5a shown in FIG. 1, and FIG. Shows an internal configuration diagram of the remote control light emitting device 5a. The remote control light emitter 5a includes a plurality of keys (buttons) B and a keyboard PCB.
(Not shown) and conductive rubber (not shown) interposed between the key B and the keyboard PCB. The keyboard PCB includes a processing circuit 5a ₁ , a clock circuit 5a ₂ and a power supply 5a _3.
In addition to the conventional configuration of the remote control transmitter unit including the above, a laser oscillation circuit 5a ₄ is mounted. Remote control light emitting device 5a, pressing key B, the conductive rubber is pressed against the key matrix portion 5a ₅ of the keyboard PCB, energized, the processing circuit 5a _1, which key B of the several certain key B is pressed Is judged. A code that does not overlap with other keys B is predetermined for each key B, and the processing circuit 5a ₁ outputs the code signal assigned to the pressed key B as serial data. is the infrared LED light emission circuit 5a _6, is transmitted after being converted into an infrared signal from the electrical signal. One of the keys is not assigned a code for remote control, and when the laser point button B ₁₂ is pressed, the laser emitting circuit 5a ₄ causes the pointer (points to the image on the screen). Laser light is turned on. The remote control light emitting device 5a includes keys (buttons) for remotely operating the OHP device 1 as well as keys for remotely operating the operation of the sheet feeder 2, such as a lighting button B ₈ , a volume button B ₉ , and an air conditioning button. B ₁₀ , a daylighting button B _11, etc. are arranged.

FIG. 8 shows (a) a transmission code structure and (b).
The name of each key B of the remote control light emitting device 5a of FIG. 7, the transmission code output when the key B is pressed, (c) the reception data output from the light receiving circuit shown in FIG. 6, and its function Is shown. The transmission signal is a serial signal,
The configuration is used when the system code for identifying the infrared remote control light-emitting device 5a, the data code which is a signal for performing an actual function, and the function cannot be represented by the number of bits of the data code. It consists of extension code. The data code when pressing each key B is 6
It is a code represented by bits and is as shown in FIG. When the light receiving circuit 41A receives a signal output by pressing each key B of the remote control light emitting device 5a, it is converted into a parallel signal and output from the processing circuit 41c.
FIG. 8C shows the output received data and the function of the sheet D for the received data. When the one-sheet feed button B ₁ is pressed, the sheet feeder 2 can feed _one sheet D. When you press the 1-sheet return button B ₂ ,
One sheet D can be returned. Fine adjustment button B ₃
Is used to move the position of the sheet D to the feeding side,
The sheet D moves only while the button is pressed. The fine adjustment return button B ₄ is used to move the position of the sheet D to the return side, and the sheet D moves only while being pressed. By pressing the sheet discharge button B ₅ , sheet D can be discharged,
When the preset button B ₆ is pressed, the transport film 36 and the like can be rewound to the first sheet D. When the stop button B ₇ is pressed, it is possible to feed one sheet, discharge the sheet, and stop the presetting. Pressing the laser point button B _12, thereby emitting a laser pointer as long as the button is held down.

Next, the basic operation of the sheet feeder 2 will be described. First, after turning on the power, switch to the sheet set path with the path switch (not shown),
Press the preset button B ₆ on the remote control light emitting device 5a. Here, a film preset command is input to the MCOM 42 from the preset button B ₆ of the remote control light emitting device 5a, a phase switching signal of a constant cycle is output to the constant current circuit 16b, and the film winding motor 16 is driven with a constant current. If the sheet position detection sensor A ₃ detects the film winding end signal, the film winding motor 16
Stop driving. Next, the sheet D is placed on the sheet feeding stand 39.
Set one. In order to detect the sheet D in the sheet detection sensor A ₁ , a phase signal of a constant cycle from the MCOM 42 is sent to the constant current circuit 33b to drive the film feed motor 33, so that the sheet D is transferred to the upper and lower films, that is, the transport film 36. Sandwiched between the holding film 37,
Set the sheet D as a unit. One sheet D
When the sheet position detection sensor A ₃ detects that the setting has been made, the driving of the film feed motor 33 is stopped. After that, the same operation as described above is repeated up to the final sheet D, and when the final sheet D is set, MC
When you press the preset button B ₆ on the OM42, MCOM4
2, a film preset command is input from the remote control receiving circuit 41, a phase switching signal of a constant cycle is output to the constant current circuit 16b, and the film winding motor 16 is driven with a constant current. When the sheet position detection sensor A ₃ detects the film rewinding end signal, the film winding motor 16 is stopped. At this point, the setting of the sheet D is completed.

When the setting of the sheet D is completed, when the one-sheet feed button B ₁ of the remote control light emitting device 5a is pressed, the MCO
A single-sheet feed command is input to the M42 from the remote control receiving circuit 41, a paper switching signal of a constant cycle is output to the constant current circuit 33b, and the film feed motor 33 is driven with a constant current. When the sheet position detection sensor A ₃ detects that one sheet D has been fed, the driving of the film feed motor 33 is stopped. Thus, the one sheet D fed out is set on the platen glass 7 of the OHP device 1, and the image of the sheet D is projected on the screen. By repeating this operation, the first sheet to the last sheet D can be sequentially set on the platen glass 7 and projected one after another.

Sheet D and platen glass 7 at this time
The positional relationship between and will be described with reference to FIG. In the sheet D, the width D ₁ in the direction perpendicular to the traveling direction (arrow K1) is smaller than the width 36D of the transport film 36 in the same direction. This is because when the sheet D is wound around the left roller 13 or the lower right roller 11, the left roller front pulley 13a, the left roller rear pulley 13b, the lower right roller front pulley 11a, and the lower right roller rear pulley 11b are displaced due to the displacement of the sheet D. This is to prevent the sheet D from colliding. The position of the sheet D with respect to the image area is detected by the sheet position detecting sensor A ₃ and the sheet D is always stopped at a position where the center of the sheet D coincides with the center of the image area.
This is to deal with the problem that the periphery of the screen is dark and the image is not clearly projected because the OHP device 1 enlarges the image information by using the lens.

When the return button B ₂ on the remote control light emitting device 5a is pressed, the remote control receiving circuit 41 is displayed on the MCOM 42.
1 sheet return command is input from the constant current circuit 1
A phase switching signal having a constant cycle is output to 6b to drive the film winding motor 16 with a constant current. When the sheet position detection sensor A ₃ detects that the sheet D has been returned by one sheet, the driving of the film winding motor 16 is stopped. As a result, the sheet one sheet before the currently projected sheet D can be set again on the platen glass 7 and projected.

When it is desired to slightly move the position of the set sheet D in the feed direction or the return direction, the fine adjustment feed button B ₃ or the fine adjustment return button B ₄ of the remote control light emitting device 5a is pressed. By operating the fine adjustment feed button B ₃ , MC
A fine adjustment feed command is input to the OM 42 from the remote control reception circuit 41, and a phase switching signal of a constant cycle is output to the constant current circuit 33b to drive the film feed motor 33 with a constant current. Also, by operating the fine adjustment return button B ₄ ,
A fine adjustment return command is input to the M42 from the remote control receiving circuit 41, a phase switching signal of a constant cycle is output to the constant current circuit 16b, and the film winding motor 16 is driven with a constant current. Both commands carry the transport film 36 and the like only while the fine adjustment feed button B ₃ or the fine adjustment return button B ₄ is pressed, and the drive is immediately stopped when the buttons B ₃ and B ₄ are released.

The feeding speeds for feeding one sheet and returning one sheet are different from the feeding speeds for finely adjusting the sheets, and the feeding speed for feeding one sheet and returning one sheet is different.
The latter is set faster than the transport speed during fine adjustment of the sheet. When you want to transport the sheet D in the return or one in one feeding is stopped, pressing the stop button B ₇ of the remote control light-emitting device 5a, is input stop command from the remote control receiver circuit 41 in MCOM42, the film feeding motor 33 The drive of the film winding motor 16 is stopped.

Next, when the sheet D is discharged to the outside of the sheet feeder 2, first, the path changeover switch is set to the discharge side, and the sheet discharge button B ₅ of the remote control light emitting device 5a is pressed, so that the MCOM 42 receives the remote control receiving circuit 41. The sheet discharge command is input to the constant current circuit 16b and a phase switching signal having a constant cycle is output to drive the film winding motor 16 at a constant current. As a result, the leading end of the sheet feeding table 39 is pressed onto the transport film 36, and a large number of sheets D on the transport film 36 are picked up one by one and discharged onto the sheet feeding table 39. It should be noted that the above-described input signal reading or load ON / OF
Control of F shall be performed by the program stored in MCOM42.

Next, in the remote control means for generating signals for controlling the sheet feeder 2 and the environmental control device,
A method of controlling lighting, volume, air conditioning, and room management will be described.

FIG. 9 is a schematic diagram of a system using the present invention.

Reference numeral 5 is an intelligent laser pointer (hereinafter referred to as "ILP") according to the present invention, 41A is a light receiving circuit shown in FIG. 6, and 2 is a sheet feeder (automatic document feeder). I ₈ identifies the received data output from the light receiving circuit 41A, and if it is a pre-assigned code, an illumination device that can turn on / off the illumination, and I 8
₉ is a speaker device that can similarly turn on / off the power of the speaker, and I ₁₀ can also turn on / off the power of the air conditioner.
An air conditioner capable of F, and I ₁₁ is a blind device that identifies received data, and a motor is driven by a code assigned in advance, and the blind can be opened and closed by this motor. Note that these devices I _{8 to} I ₁₁ correspond to the buttons B _{8 to} B ₁₁ of the intelligent laser pointer 5 shown in FIG. 7, and by pressing these buttons, the devices are activated. Is becoming

The light receiving circuit 41A receives the transmission signal from the ILP5.
Converts it to a parallel electric signal and outputs it. As shown in FIG. 8C, codes that do not overlap with each other are assigned in advance to the respective devices. The reception data output from the light receiving circuit 41A is sent to each device. Each device identifies the code of the data sent here. As a result of the identification of the code, if the illumination device I ₈ matches the assigned code, the illumination equipment such as a fluorescent lamp and the light source 9 of the OHP device 1 are currently turned on and turned off, If it is off, it turns on and lights up. As a result of the identification of the code, the speaker device I ₉ turns off if the power supply for operating the speaker is currently ON if the code matches the assigned code, and the current O
If it is FF, it is turned on. As a result of the identification of the code, the air conditioner I ₁₀ finds that if it matches the assigned code, if the power supply for operating the air conditioner is currently ON, it is OF.
F, and if it is currently OFF, turn it ON. Blind device I
₁₁ result of the identification code, if consistent with the assigned code, as long as the state in which the blind is to be incident the current sunlight, motor drives in a direction so as to block light blocks light If the current light is blocked, the motor can be driven in the opposite direction to allow the light to enter.

That is, the light receiving circuit 41A has a lighting remote control means, an AV remote control means, and an air conditioning remote control for controlling the lighting device I ₈ , the speaker device I ₉ , the air conditioner device I ₁₀ , and the blind device I ₁₁ , respectively. Means and room remote control means (neither shown) are installed.

Alternatively, a plurality of light receiving circuits 41A may be installed, and each light receiving circuit may be individually provided with a lighting device I ₈ , a speaker device I ₉ , an air conditioner device I ₁₀ , and a blind device I ₁₁ .

[0048]

As described above, according to the present invention,
By incorporating the remote control means integrally with the laser pointer, when performing a presentation using the OHP device, the OHP device is not moved beside the OHP device, and the OHP device is not moved.
In addition to being able to operate the device, a small number of staff or one presenter can remotely operate various environmental control devices such as a lighting device on the spot, so that the presentation can be efficiently performed.

Further, the functions for operating various environmental control devices such as the laser pointer, the lighting device, the speaker device, etc. can be integrated into one lightweight and compact remote control means, and the operability is remarkably improved. It is possible to realize a comfortable and highly effective presentation.

[Brief description of drawings]

FIG. 1 is a longitudinal sectional view of an OHP device and a sheet feeder and an enlarged perspective view of a remote control light emitting device.

FIG. 2 is a top view development view of a configuration of a sheet feeder and a drive system.

FIG. 3 is a top view showing a positional relationship between a platen glass and a sheet.

FIG. 4 is an electrical configuration diagram of a sheet feeder.

FIG. 5 is a hard block diagram of the sheet feeder.

6A and 6B are circuit configuration diagrams of a remote control light receiving circuit.

FIG. 7A is an internal configuration diagram of a remote control light emitting device, and FIG.
Is a perspective view of the remote control light emitting device.

8A is a diagram showing a transmission code configuration, FIG. 8B is a diagram showing a relationship between a key and a data code, and FIG. 8C is a diagram showing a relationship between a key and received data and a function.

FIG. 9 is an overall configuration diagram of an overhead projector.

[Explanation of symbols]

 1 OHP device 2 Automatic document feeder (sheet feeder) 3 Overhead projector 5 Intelligent laser pointer 5a Remote operation means (remote control light emitter) 7 Platen glass 42 Control means (MCOM) D Original film (sheet)

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Noriaki Nakazawa Inventor Noriaki Nakazawa 5540-11 Sakate-cho, Suikaido City, Ibaraki Canon Inc. (72) Inventor Kenji Kobayashi 3-30-2 Shimomaruko, Ota-ku, Tokyo Canon Inc. In the company

Claims (9)

[Claims] 1. An intelligent laser pointer, characterized in that, in a laser pointer for pointing an image projected by a projector with a laser beam, remote control means for generating a signal for controlling a presentation environment is integrally incorporated. 2. An OHP device for projecting a document film, an automatic document feeder for sequentially transporting the document film to a predetermined position of a platen glass of the OHP device, the OHP device and the automatic document feeder. The intelligent laser pointer according to claim 1, wherein the intelligent laser pointer is configured by an OHP system including a control unit that controls the device, and the remote operation unit remotely operates the control unit. 3. The intelligent laser pointer according to claim 1, further comprising lighting remote control means for generating a signal for controlling the light source. 4. A for generating a signal for controlling the volume
The intelligent laser pointer according to claim 1, further comprising V remote control means. 5. At least one of temperature, ventilation and humidity
The intelligent laser pointer according to claim 1, further comprising air conditioning remote control means for generating a signal for controlling one of the two. 6. The intelligent laser pointer according to claim 1, further comprising a room management remote control means for generating a signal for controlling lighting. 7. The intelligent laser pointer according to claim 1, further comprising a drive source common to the remote control means. 8. The intelligent laser pointer according to claim 1, wherein the pointing direction is the same as the directivity of the remote control means. 9. An original film formed by writing image information on a transparent film is placed on a platen glass,
OH for projecting image information by irradiating the original film with light
An overhead projector, comprising: a P device; and the intelligent laser pointer according to any one of claims 1 to 8.